A system comprising a robotic arm, a plurality of grabbers, a sensor, and a preparation cup. The robotic arm has a first end and a recessed portion. The grabbers are coupled to the robotic arm at the first end. The sensor is positioned inside the recessed portion of the robotic arm at a first distance from the first end and at a first angle. The preparation cup is coupled to wings having a body portion, a first extended portion, and a second extended portion. The body portion is coupled to a portion of the preparation cup, the first extended portion extends in a first direction and the second extended portion extends in a second direction. The wings are operable to be magnetically coupled to the plurality of grabbers via the first and second extended portions.

A system comprising a robotic arm, a plurality of grabbers, a sensor, and a preparation cup. The robotic arm has a first end and a recessed portion. The grabbers are coupled to the robotic arm at the first end. The sensor is positioned inside the recessed portion of the robotic arm at a first distance from the first end and at a first angle. The preparation cup is coupled to wings having a body portion, a first extended portion, and a second extended portion. The body portion is coupled to a portion of the preparation cup, the first extended portion extends in a first direction and the second extended portion extends in a second direction. The wings are operable to be magnetically coupled to the plurality of grabbers via the first and second extended portions.

A method of operating a robotic attacher, comprises extending a robotic attacher between the legs of a dairy livestock. The method further comprises attaching milking equipment to the dairy livestock using a gripping portion of the robotic attacher during a milking operation, wherein the gripping portion has a nozzle that is positioned away from a teat of the dairy livestock during the milking operation. The method further comprises rotating the gripping portion of the robotic attacher so that the nozzle is positioned to face a teat of the dairy livestock during a spraying operation.

A system that includes a three-dimensional (3D) camera configured to capture a 3D image of a rearview of a dairy livestock in a stall, a memory, and a processor. The processor is configured to obtain the 3D image, identify one or more regions within the 3D image comprising depth values greater than a depth value threshold, and apply the thigh gap detection rule set to the one or more regions to identify a thigh gap region. The processor is further configured to demarcate an access region within the thigh gap region and demarcate a tail detection region. The processor is further configured to partition the 3D image within the tail detection region to generate a plurality of image depth planes, examine each of the plurality of image depth planes, and determine position information for the tail of the dairy livestock in response to identifying the tail of the dairy livestock.

A system that includes a three-dimensional (3D) camera configured to capture a 3D image of a rearview of a dairy livestock in a stall, a memory, and a processor. The processor is configured to obtain the 3D image, identify one or more regions within the 3D image comprising depth values greater than a depth value threshold, and apply the thigh gap detection rule set to the one or more regions to identify a thigh gap region. The processor is further configured to demarcate an access region within the thigh gap region and demarcate a tail detection region. The processor is further configured to partition the 3D image within the tail detection region to generate a plurality of image depth planes, examine each of the plurality of image depth planes, and determine position information for the tail of the dairy livestock in response to identifying the tail of the dairy livestock.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A system for operating a robotic arm, comprises a camera, a controller and a robotic arm. The camera captures an image of a rear of a dairy livestock located in a stall of a rotary milking platform. The controller receives the image and in conjunction with the stall of the rotary milking platform in which a dairy livestock is located moving into an area adjacent a robotic arm, determines whether a milking cluster is attached to the dairy livestock based at least in part upon the image. The robotic arm is communicatively coupled to the controller and extends between the legs of the dairy livestock if the controller determines that the milking cluster is not attached to the dairy livestock. The robotic arm does not extend between the legs of the dairy livestock if the controller determines that the milking cluster is attached to the dairy livestock.

A system for operating a robotic arm, comprises a camera, a controller and a robotic arm. The camera captures an image of a rear of a dairy livestock located in a stall of a rotary milking platform. The controller receives the image and in conjunction with the stall of the rotary milking platform in which a dairy livestock is located moving into an area adjacent a robotic arm, determines whether a milking cluster is attached to the dairy livestock based at least in part upon the image. The robotic arm is communicatively coupled to the controller and extends between the legs of the dairy livestock if the controller determines that the milking cluster is not attached to the dairy livestock. The robotic arm does not extend between the legs of the dairy livestock if the controller determines that the milking cluster is attached to the dairy livestock.

In certain embodiments, a system for applying disinfectant to the teats of a dairy livestock includes a carriage mounted on a track, the carriage operable to translate laterally along the track. The system further includes a robotic arm including a first member pivotally attached to the carriage such that the first member may rotate about a point of attachment to the carriage, a second member pivotally attached to the first member such that the second member may rotate about a point of attachment to the first member, and a spray tool member pivotally attached to the second member such that the spray tool member may rotate about a point of attachment to the second member. The robotic arm further includes a spray tool attached to the spray tool member. The system further includes a controller operable to cause at least a portion of the robotic arm to extend between the hind legs of a dairy livestock such that the spray tool is located at a spray position from which the spray tool may discharge an amount of disinfectant to the teats of the dairy livestock.